JP7180741B2 - porcelain pipe unit - Google Patents

Description

The present invention relates to a porcelain pipe unit.

The insulator unit (epoxy unit) described in Patent Document 1 integrally includes an inner conductor (center conductor) connected to the end of a power cable, and an insulator tube (insulating tube) made of epoxy resin covering the inner conductor. A cylindrical ground electrode (shielding electrode) surrounding one end of the inner conductor is embedded in the insulator. The ground electrode is drawn out from the one end of the insulator tube and is electrically connected to the ground potential when the insulator unit is in use. By providing the ground electrode, it is possible to shield the electric field on the inner peripheral side of the ground electrode, thereby reducing the electric field intensity around the insulator. The inner peripheral surface of the porcelain insulator has an arrangement surface (receiving portion) into which the stress cone attached to the outer peripheral portion of the end of the power cable is inserted and arranged.

JP 2014-45553 A

In the insulator unit described in Patent Document 1, since the ground electrode is formed up to a position overlapping the arrangement surface when viewed from the radial direction, the insulator may be increased in size. This will be explained below.

First, the placement surface needs to have a large inner diameter so that the stress cone attached to the power cable can be inserted. In addition, if the inner and outer peripheral portions of the ground electrode in the porcelain pipe are excessively thin, there is a risk of problems in manufacturing such as short shots (improper molding), so a certain amount of wall thickness is required. . Therefore, in the axial region where the ground electrode and the arrangement surface overlap when viewed from the radial direction, the outer diameter of the porcelain insulator must be increased. As a result, in the insulator unit described in Patent Document 1, the size of the insulator may be increased.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a porcelain pipe unit capable of reducing the size of the porcelain pipe.

In order to achieve the above object, the present invention provides an inner conductor electrically connected to a terminal of a power cable, a porcelain tube covering the inner conductor, and a porcelain insulator buried inside the porcelain tube and surrounding the inner conductor. a ground electrode formed thereon, wherein the inner peripheral surface of the porcelain insulator has an arrangement surface on which the stress cone attached to the power cable is arranged, and a flange member having an attachment surface on which an external equipment box is attached. When the side of the inner conductor to which the terminal of the power cable is connected is the base end side, and the side opposite to the base end side is the tip side, the arrangement surface is closer to the base than the mounting surface. A porcelain tube unit is provided, which is arranged on an end side, and wherein the ground electrode is arranged on the tip side of the mounting surface.

ADVANTAGE OF THE INVENTION According to this invention, it becomes possible to provide the porcelain pipe unit which can make a porcelain pipe small.

Fig. 3 is an exploded cross-sectional view of an insulator tube unit and a cable assembly of the power cable connection structure according to the embodiment; 1 is a cross-sectional view of a power cable connection structure in an embodiment; FIG. FIG. 3 is a cross-sectional view enlarging a part of FIG. 2; It is a side view of a flange member in an embodiment. It is a sectional view of a flange member in an embodiment. It is a front view of a flange member in an embodiment. It is a rear view of a flange member in an embodiment. FIG. 4 is a side view of a ground electrode, a plurality of embedded conductive members, and a plurality of connection members in the embodiment;

[Embodiment]
An embodiment of the present invention will be described with reference to FIGS. 1 to 8. FIG. It should be noted that the embodiment described below is shown as a preferred specific example for carrying out the present invention, and there are portions that specifically illustrate various technically preferable technical matters. , the technical scope of the present invention is not limited to this specific embodiment.

(Power cable connection structure 10)
FIG. 1 is an exploded cross-sectional view of a power cable connection structure 10 according to the present embodiment, in which an insulator unit 1 and a cable assembly 7 are exploded. FIG. 2 is a cross-sectional view of the power cable connection structure 10. As shown in FIG. FIG. 3 is an enlarged view of a part of FIG.

As shown in FIG. 2, the power cable connection structure 10 is used by being attached to an equipment box 100 as a member to be attached, which is arranged on the roof of a railroad vehicle, for example. Although the details will be described later, the power cable connection structure 10 is attached to the equipment box 100 in a state in which a part thereof protrudes into the internal space 100a inside the equipment box 100 . The power cable connection structure 10 is for connecting a power cable 71 to which a high voltage is applied and an electric path (not shown) connected thereto while ensuring electrical insulation from the surroundings. 1 and 2, a porcelain pipe unit 1 and a cable assembly 7 are assembled.

(Insulator unit 1)
The porcelain pipe unit 1 includes a porcelain pipe structure 2 integrally formed with a porcelain pipe 21 and a flange member 3 fixed to the porcelain pipe structure 2 . The porcelain pipe structure 2 is formed by embedding an internal conductor 22, a ground electrode 23 and the like in a porcelain pipe 21 made of epoxy resin. The insulator structure 2 is formed by arranging the inner conductor 22, the ground electrode 23, etc. inside the mold for the insulator 21, pouring molten epoxy resin into the mold, and curing the insulator 21, the inner conductor 22, and the ground. The electrodes 23 and the like are integrally formed.

Note that the axial direction of the insulator unit 1 (that is, the axial direction of the inner conductor 22 and the axial direction of the insulator 21, and the horizontal direction in FIGS. 1 to 3) is simply referred to as the axial direction. In addition, the side of the inner conductor 22 to which the power cable 71 is connected (for example, the right side in FIGS. 1 to 3), which is one side in the axial direction, is referred to as the axial base end side, and the opposite side (for example, FIGS. The left side of FIG. 3) is referred to as the tip side in the axial direction. In addition, simply referring to the circumferential direction means the circumferential direction around the central axis of the power cable connection structure 10, and simply referring to the radial direction means the radial direction of the power cable connection structure 10 centering on the central axis. shall mean

The internal conductor 22 has a substantially rod shape elongated in the axial direction. The inner conductor 22 is embedded in the insulator 21 while protruding from the insulator 21 at its tip end in the axial direction. An end portion of the inner conductor 22 protruding from the porcelain tube 21 is electrically connected to an electric path (not shown) to which the power cable 71 is connected via a terminal fitting 8 fixed to the exposed portion.

As shown in FIG. 3 , a bottomed tubular portion 220 that is open to the axial base end side is formed at the end portion of the inner conductor 22 on the axial base end side. The bottomed tubular portion 220 has a bottom wall portion 221 and a hollow tubular wall portion 222 extending from the bottom wall portion 221 toward the base end side in the axial direction.

The outer peripheral surface of the bottom wall portion 221 is tapered such that the diameter increases toward the base end side in the axial direction. The bottom wall portion 221 is formed with a boss portion 221a protruding toward the base end side in the axial direction. A female screw hole is provided in the boss portion 221a, and a contact member 4 for detachably connecting the inner conductor 22 and the power cable 71 is bolted. The contact member 4 can be a tulip contact, for example, and detachably connects the inner conductor 22 and the power cable 71 .

The cylindrical wall portion 222 extends from the outer peripheral edge of the bottom wall portion 221 toward the base end side in the axial direction, and surrounds the connecting portion between the power cable 71 and the internal conductor 22 via the contact member 4 . The cylindrical wall portion 222 includes a cylindrical portion 222a formed straight along the axial direction from the bottom wall portion 221, and an enlarged diameter portion 222b having both an inner diameter and an outer diameter that increase toward the base end side in the axial direction from the cylindrical portion 222a. and The inner peripheral surface of the tubular wall portion 222 is exposed from the porcelain pipe 21 .

As shown in FIGS. 1 and 2, the porcelain pipe 21 is made of epoxy resin and formed into a generally tubular shape elongated in the axial direction. In particular, when the power cable connection structure 10 is installed outdoors such as on the roof of a railroad vehicle, it is preferable to use epoxy resin, which has excellent weather resistance, as the resin constituting the porcelain pipe 21 .

Annular cap portions 211 projecting outward are provided at a plurality of locations in the axial direction X at predetermined intervals on the outer peripheral portion of the porcelain pipe 21 . By forming the plurality of cap portions 211 on the insulator 21, the creepage distance of the outer peripheral surface of the insulator 21 can be secured, and the occurrence of creeping discharge along the surface of the insulator 21 can be suppressed. In this embodiment, the outer diameters of the plurality of cap portions 211 are equal to each other. When the outer diameter of the cap portion 211 having the largest outer diameter among the plurality of cap portions 211 is defined as the maximum outer diameter, and the outer diameter of the cap portion 211 having the smallest outer diameter among the plurality of cap portions 211 is defined as the minimum outer diameter. , the ratio of the maximum outer diameter to the minimum outer diameter, that is, "maximum outer diameter/minimum outer diameter" is preferably 1.1 or less, more preferably 1.05 or less. Further, in this embodiment, the outer diameter of each cap portion 211 is the same as the outer diameter of the end portion of the insulator 21 on the base end side in the axial direction.

An electric field shielding layer 5 is formed on the outer peripheral surface of the porcelain tube 21 . The electric field shielding layer 5 extends from the end of the insulator 21 on the proximal side in the axial direction to a position in front of the cap portion 211 of the plurality of cap portions 211 of the insulator 21 that is positioned closest to the proximal side in the axial direction. formed. In this embodiment, the electric field shielding layer 5 is formed up to a position on the tip end side in the axial direction with respect to an embedded conductive member 25 which will be described later. The electric field shielding layer 5 is formed all around the outer peripheral surface of the insulator 21 . The electric field shielding layer 5 has a role of suppressing an increase in the electric field intensity around the insulator 21 by shielding the electric field in the region on the inner peripheral side thereof. The electric field shielding layer 5 is made of, for example, a conductive paint applied to the outer peripheral surface of the porcelain insulator 21 .

The inner peripheral surface of the porcelain pipe 21 has an arrangement surface 212 with which the stress cone 73 is arranged in contact. The arrangement surface 212 has a shape corresponding to the outer shape of the stress cone 73 arranged inside thereof. have. In addition, the inner peripheral surface of the porcelain insulator 21 is provided with a cylindrical surface 213 formed along the axial direction from the inclined arrangement surface 212a to the base end side in the axial direction. A portion of the cylindrical surface 213 on the tip side in the axial direction also constitutes an arrangement surface 212 on which the stress cone 73 is arranged in contact. A plurality of nut members 24 for fixing the insulator 21 to the flange are embedded on the outer peripheral side of the placement surface 212 of the insulator 21 .

As shown in FIG. 3, the nut member 24 is a cap nut that is elongated in the axial direction and provided with a female screw hole 240 that opens to the end surface on the proximal end side in the axial direction. The nut member 24 is exposed from the porcelain tube 21 at its proximal end in the axial direction. The flange member 3 is fastened to each nut member 24 with a bolt B1.

As shown in FIG. 2, the flange member 3 is attached to the equipment box 100. As shown in FIG. The equipment box 100 is at the ground potential when installed on the roof of the railway. becomes.

FIG. 4 is a side view of the flange member 3. FIG. 5 is a cross-sectional view of the flange member 3. FIG. FIG. 6 is a front view of the flange member 3. FIG. 7 is a rear view of the flange member 3. FIG. The flange member 3 is cup-shaped and has a flange bottom wall 31 , a flange side wall 32 and a flange mounting wall 33 . The flange bottom wall 31 is formed in a disk shape with an opening hole 311 provided in the center, and as shown in FIG. The flange member 3 is fixed to the insulator pipe 21 by inserting the bolt B1 through the through hole 310 provided in the flange bottom wall 31 and screwing it into the female screw hole 240 of the nut member 24 .

As shown in FIGS. 4 and 5, the flange side wall 32 is cylindrical. The flange side wall 32 is provided with three member placement portions 321 in which the outer peripheral surface protrudes toward the outer peripheral side and the inner peripheral surface is recessed toward the outer peripheral side. The member placement portion 321 is formed with a female screw hole 321c that opens to a bottom surface 321b of a recess 321a formed on the inner peripheral side of the member placement portion 321 . As shown in FIG. 3, a bolt B2 is screwed into the female threaded hole 321c, and a connecting member 6, which will be described later, is fixed to the flange member 3 using the bolt B2.

An axial tip side of the concave portion 321a is closed by an inclined surface 321d. 321 d of inclined surfaces are surfaces which incline so that it may go to an inner peripheral side, so that it goes to an axial direction front-end|tip side. By making the surface that closes the tip side in the axial direction of the concave portion 321a an inclined surface like the inclined surface 321d, the space around the connection member 6 can be widened, and the connection member 6 can be placed in the flange member 3 and embedded (described later). It is possible to prevent the connecting member 6 from interfering with the flange member 3, the porcelain pipe 21, etc. during the operation of fixing to the conductive member 25. FIG.

A pair of flange mounting walls 33 are provided so as to protrude from the end portion of the flange side wall 32 on the tip end side in the axial direction to both sides in a direction orthogonal to the axial direction. Each flange mounting wall 33 has a surface on the tip side in the axial direction forming a mounting surface 331 to which the equipment box 100 is mounted. As shown in FIGS. 2 and 3, the insulator unit 1 is inserted into the internal space 100a of the equipment box 100 through the mounting hole 100b provided in the equipment box 100, and the mounting surface 331 of the flange mounting wall 33 100 faces the wall around the mounting hole 100b.

Bolt insertion holes 33a and 100c communicating with each other are formed in the flange mounting wall 33 and the equipment box 100, respectively. In the flange mounting wall 33 and the equipment box 100, the bolt B3 is inserted through the bolt insertion hole 33a and the bolt insertion hole 100c, and the nut N is screwed onto the bolt B3 protruding from the bolt insertion hole 100c toward the base end side in the axial direction. are bolted to each other. When the flange mounting wall 33 is fastened to the equipment box 100 installed on the roof of the railroad, the flange mounting wall 33 has the same potential as the equipment box 100, that is, the ground potential. A ground electrode 23 is embedded in the insulator 21 so as to be electrically connected to the flange member 3 .

The ground electrode 23 is formed in a cylindrical shape along the axial direction, and surrounds part of the inner conductor 22 from the outer peripheral side. In this embodiment, the ground electrode 23 is a cylindrical metal mesh, and is formed with a large number of holes (that is, mesh portions). Forming defects of the porcelain insulator 21 can be suppressed by forming the ground electrode 23 with a large number of holes. That is, the insulator 21 is formed by insert molding in which the ground electrode 23 and the like are arranged in a mold. sufficiently flows into the inner and outer peripheries of the mold, and the occurrence of molding defects is suppressed. Both ends of the ground electrode 23 in the axial direction have a shape wound toward the inner peripheral side. Note that the ground electrode 23 is not limited to a metal mesh, and may be a tubular conductor with a large number of holes such as slits or punch holes, a tubular conductor without holes, or the like, which shields the surrounding electric field. If possible, it is also possible to employ other structures.

The position of the end portion of the ground electrode 23 on the base end side in the axial direction is at a position away from the arrangement surface 212 toward the distal end side in the axial direction. In addition, the position of the end portion of the ground electrode 23 on the base end side in the axial direction is slightly toward the distal end side in the axial direction from the boundary position between the cylindrical portion 222a and the enlarged diameter portion 222b. Furthermore, the end portion of the ground electrode 23 on the proximal side in the axial direction is located on the proximal side in the axial direction with respect to the mounting surface 331 . When viewed from the radial direction, the portion of the ground electrode 23 on the base end side in the axial direction overlaps the portion of the electric field shielding layer 5 on the tip side in the axial direction.

The position of the end of the ground electrode 23 on the distal end side in the axial direction is located on the distal end side in the axial direction with respect to the mounting surface 331 . In addition, the end portion of the ground electrode 23 on the tip end side in the axial direction is located on the tip end side in the axial direction than the bottom wall portion 221 of the bottomed cylindrical portion 220 of the internal conductor 22 . Note that the position of the end portion of the ground electrode 23 on the distal end side in the axial direction is not limited to this, and the position of the end portion on the distal end side in the axial direction is positioned, for example, on the proximal end side in the axial direction from the boundary between the bottom wall portion 221 of the bottomed cylindrical portion 220 and the cylindrical portion 222a. You may have

Further, the axial distal end of the ground electrode 23 is positioned closer to the axial proximal end than the axial distal end of the large-diameter cap 214a, which will be described later. The large-diameter capped surface 214a is the capped surface 214 that has a larger outer diameter than the other capped surfaces 214 among the capped portions 214 that connect axially adjacent capped portions 211 on the outer peripheral surface of the porcelain insulator 21 . In this embodiment, the large-diameter kasama surface 214a is the kasama surface 214 located at the end portion on the axial base end side and the kasama surface 214 adjacent to the kasama surface 214 on the axial tip side of the plurality of kasama surfaces 214. . The ground electrode 23 is configured to be electrically conductive with the outside of the insulator 21 via an embedded conductive member 25 connected thereto.

As shown in FIG. 3, the embedded conductive member 25 is a cylindrical conductor extending radially outward from the ground electrode 23, and is embedded in the insulator 21 with its radially outer end exposed. The embedded conductive member 25 is exposed in the region where the electric field shielding layer 5 is formed on the outer peripheral surface of the insulator 21 .

FIG. 8 is a side view of the ground electrode 23, the plurality of embedded conductive members 25, and the plurality of connecting members 6. FIG. The end of the embedded conductive member 25 on the ground electrode 23 side is joined to the ground electrode 23 by welding or the like. In this embodiment, embedded conductive members 25 are connected to the ground electrode 23 at three locations in the circumferential direction. The three embedded conductive members 25 are formed at the same position in the axial direction and are formed at intervals of 90° in the circumferential direction. A female threaded hole 251 opening radially outward is formed in the embedded conductive member 25 . A connection member 6 is fastened to the embedded conductive member 25 using a bolt B4.

As shown in FIG. 8, three connection members 6 are provided and connected to three embedded conductive members 25, respectively. The connection member 6 is formed by bending a long plate-shaped conductor, and includes a first connection portion 61 , an inclined portion 62 and a second connection portion 63 .

As shown in FIG. 3 , the first connecting portion 61 is formed along the axial direction and overlapped with the embedded conductive member 25 in the radial direction with the electric field shielding layer 5 interposed therebetween. The first connection portion 61 is fastened to the embedded conductive member 25 by inserting the bolt B4 through the through hole 611 formed in the first connection portion 61 and screwing it into the female screw hole 251 of the embedded conductive member 25 . there is When the first connecting portion 61 is fastened to the embedded conductive member 25 using the bolt B4, the connecting member 6, the electric field shielding layer 5, the embedded conductive member 25, and the ground electrode 23 are electrically connected to each other. becomes.

The inclined portion 62 is formed to connect the first connection portion 61 and the second connection portion 63, and is formed so as to be inclined radially outward toward the axial base end side. The inclined portion 62 faces the inclined surface 321 d of the flange member 3 .

The second connecting portion 63 is formed along the axial direction and overlaps the bottom surface 321 b of the recess 321 a of the member placement portion 321 . The second connection portion 63 is fastened to the flange member 3 by inserting the bolt B2 through the through hole 631 formed in the second connection portion 63 and screwing it into the female screw hole 321c provided in the member placement portion 321. It is The second connecting portion 63 and the bolt B2 are arranged so as to be accommodated within the member placement portion 321 of the flange side wall 32 . A cable assembly 7 is connected to the insulator unit 1 from the base end side of the flange member 3 .

(cable assembly 7)
As shown in FIGS. 1 and 2, the cable assembly 7 includes a power cable 71, a connection terminal 72, a stress cone 73, a compressing device 74, and a cover member 75. As shown in FIG. The power cable 71 includes a cable conductor 711 , a cable inner semiconductive layer (not shown), a cable insulator 712 , a cable outer semiconductive layer 713 , a cable shield layer 714 and a cable sheath 715 in order from the center. The power cable 71 is stripped so that a cable conductor 711, a cable insulator 712, a cable outer semi-conductive layer 713, and a cable shield layer 714 are exposed in this order from the tip in the axial direction.

The connection terminal 72 is crimped onto the cable conductor 711 and fixed to the cable conductor 711 in an unremovable manner. The connection terminal 72 is a terminal for connecting the power cable 71 to the contact member 4 , and an axially distal end of the connection terminal 72 is inserted into the contact member 4 . The connection terminal 72 is detachably connected to the contact member 4 so that it can be pushed into and inserted into the contact member 4 and can also be pulled out from the contact member 4 .

The stress cone 73 is fitted around the outer periphery of the cable insulator 712 and the cable outer semi-conductive layer 713 . The stress cone 73 is axially compressed by the compression device 74 and is in contact with both the power cable 71 and the mounting surface 212 of the porcelain pipe 21 .

In this embodiment, the stress cone 73 is composed of two members, and includes an insulating portion 731 on the axial distal end side and a semiconductive portion 732 on the axial proximal end side. The outer peripheral surface of the insulating portion 731 has an inclined outer peripheral surface 731a that is inclined from the axial distal end side toward the axial proximal end side. is doing. The semiconducting portion 732 has an inner peripheral portion in contact with the cable outer semiconducting layer 713 and is connected to the ground potential via the cable outer semiconducting layer 713 . An annular stopper 76 is fitted to the outer peripheral portion of the power cable 71 on the axial tip side of the stress cone 73 . The stopper 76 has a role of receiving compressive force acting on the stress cone 73 in the axial direction from the compressing device 74 , and is in contact with the end surface of the inner conductor 22 on the proximal side in the axial direction.

The compression device 74 is for axially compressing the stress cone 73 . The compression device 74 is in contact with the stress cone 73 at its distal end in the axial direction, and locked to the cover at its proximal end in the axial direction. Then, the compressing device 74 presses the stress cone 73 toward the distal end side in the axial direction by, for example, the reaction force of the coil spring 741 . In this embodiment, the entire compression device 74 is made of a conductive material, but at least a part of it may be made of a non-conductive material.

The cover member 75 has a first cover 751 and a second cover 752 fixed to each other. The first cover 751 is fastened to the flange member 3 using stud bolts 77 or the like screwed into the flange bottom wall 31 . In the power cable connecting structure 10, the first cover 751 surrounds the power cable 71, the stress cone 73, and the compression device 74 projecting axially from the flange member 3 toward the base end side. A sealing portion 78 seals between the end of the first cover 751 on the proximal side in the axial direction and the power cable 71 . The sealing portion 78 is formed by winding polyethylene tape, epoxy tape, or the like provided with an adhesive material, and liquid-tightly seals the space between the first cover 751 and the power cable 71 .

The second cover 752 is fixed to the first cover 751 from the axial base end side of the first cover 751 and surrounds the sealing portion 78 from the outer peripheral side. The end portion of the second cover 752 on the proximal side in the axial direction is tightened by the tightening member 70 and tightly attached to the power cable 71 via the elastic sheet 79 .

(Actions and effects of the embodiment)
In this embodiment, the end portion of the ground electrode 23 on the proximal side in the axial direction is located on the distal side in the axial direction with respect to the placement surface 212 with which the stress cone 73 is placed in contact. Therefore, the size of the porcelain insulator 21 can be reduced. This will be explained below.

First, the placement surface 212 needs to have a somewhat large inner diameter so that the stress cone 73 attached to the power cable 71 can be inserted. The outer diameter of the region must also be increased. In addition, the inner and outer peripheral portions of the insulator tube 21 of the ground electrode 23 must be thickened to a certain extent because if they are too thin, problems such as short shots may occur in manufacturing. Therefore, when the ground electrode 23 is formed to a position that overlaps with the arrangement surface 212 when viewed from the radial direction, the insulator pipe 21 is not in the axial region where the ground electrode 23 and the arrangement surface 212 overlap in the radial direction. There is no choice but to increase the outer diameter, which may lead to an increase in the size of the porcelain pipe 21 . On the other hand, in the present embodiment, as described above, the end portion of the ground electrode 23 on the base end side in the axial direction is positioned further on the distal end side in the axial direction than the placement surface 212, so that the insulator 21 can be made smaller. .

Further, an electric field shielding layer 5 for shielding an electric field is formed on the outer peripheral surface of the porcelain tube 21 closer to the base end in the axial direction than the earth electrode 23 . Therefore, the electric field is shielded by the electric field shielding layer 5 in the area of the porcelain tube 21 closer to the base end in the axial direction than the ground electrode 23 . Furthermore, in this embodiment, when viewed from the radial direction, the ground electrode 23 and the electric field shielding layer 5 partially overlap each other. Therefore, the electric field can be shielded in a wide axial region from the end of the ground electrode 23 on the distal end side in the axial direction to the end of the electric field shielding layer 5 on the proximal end side in the axial direction. It is possible to suppress an increase in the electric field strength of

Moreover, the insulator unit 1 further includes a flange member 3 . The placement surface 212 is arranged on the base end side in the axial direction with respect to the mounting surface 331 . Therefore, the projecting length of the porcelain pipe unit 1 projecting from the mounting surface 331 toward the tip side in the axial direction (that is, the internal space 100a of the equipment box 100) can be reduced. In many cases, a plurality of wirings are installed in the equipment box 100, and if the porcelain pipe unit 1 protrudes greatly into the equipment box 100, electrical insulation from nearby wiring may decrease. By reducing the protruding length of the insulator unit 1 protruding into the internal space 100a of the insulator 100, it is possible to suppress deterioration in electrical insulation from wiring in the vicinity of the insulator unit 1. The ground electrode 23 is arranged on the distal end side of the mounting surface 331 in the axial direction. Therefore, the electric field in the insulator 21 projecting into the equipment box 100 can be shielded.

A connection member 6 electrically connected to the embedded conductive member 25 and the flange member 3 is fixed to the inner peripheral side of the flange side wall 32 . Therefore, in the equipment box 100, it is possible to prevent the formation of a region where the electric field strength is high. For example, when the connection member 6 is fixed to the mounting surface 331 of the flange member 3, a bolt or the like for fixing the connection member 6 protrudes from the mounting surface 331 into the equipment box 100, and the electric field intensity around the bolt is high. may become Therefore, by fixing the connection member 6 to the inner peripheral side of the flange side wall 32, the bolt B2 or the like for fixing the connection member 6 to the flange member 3 protrudes greatly into the equipment box 100, and the electric field is generated in the equipment box 100. It is possible to suppress the formation of a portion with high strength.

As described above, according to this embodiment, it is possible to provide a porcelain pipe unit in which the size of the porcelain pipe can be reduced.

(Summary of embodiment)
Next, technical ideas understood from the embodiments described above will be described with reference to the reference numerals and the like in the embodiments. However, each reference numeral and the like in the following description do not limit the constituent elements in the claims to the members and the like specifically shown in the embodiment.

[1] An inner conductor (22) electrically connected to the end of a power cable (71), a porcelain tube (21) covering the inner conductor (22), and a porcelain tube (21) embedded inside the porcelain tube (21) A ground electrode (23) formed to surround the inner conductor (22), and a stress cone (73) attached to the power cable (71) is arranged on the inner peripheral surface of the insulator tube (21). and a flange member (3) having a mounting surface to which an external equipment box (100) is mounted, wherein the end of the power cable (71) in the inner conductor (22) When the side to which is connected is the proximal side and the side opposite to the proximal side is the distal side, the arrangement surface (212) is arranged closer to the proximal side than the mounting surface (331), The insulator unit (1), wherein the ground electrode (23) is arranged closer to the tip than the mounting surface (331).

[2] The above [1], wherein an electric field shielding layer (5) for shielding an electric field is formed on the outer peripheral surface of the porcelain insulator (21) closer to the proximal end than the ground electrode (23). porcelain pipe unit (1).

[3] The porcelain tube unit (1) according to [2], wherein the ground electrode (23) and the electric field shielding layer (5) partially overlap each other when viewed from the radial direction.

[4] An embedded conductive member (25) partially exposed and embedded in the insulator (21) and electrically connected to the ground electrode (23); the embedded conductive member (25) and the flange; a connection member (6) electrically connected to the member (3), wherein the flange member (3) includes a flange mounting wall (33) having the mounting surface (331); and a flange side wall (32) formed on the base end side from (33) and surrounding the insulator pipe (21), and the connecting member (6) is fixed to the inner peripheral side of the flange side wall (32). The porcelain pipe unit (1) according to [4] above.

(Appendix)
Although the embodiments of the present invention have been described above, the above-described embodiments do not limit the invention according to the scope of claims. Also, it should be noted that not all combinations of features described in the embodiments are essential to the means for solving the problems of the invention. Moreover, the present invention can be modified appropriately without departing from the gist thereof.

1... porcelain pipe unit 100... equipment box (attached member)
2 Porcelain pipe structure 21 Porcelain pipe 212 Arrangement surface 22 Internal conductor 23 Earth electrode 25 Embedded conductive member 3 Flange member 32 Flange side wall 33 Flange mounting wall 331 Mounting surface 5 Electric field shielding layer 6 Connection Conductor 71... Power cable 73... Stress cone

Claims (4)

an inner conductor electrically connected to the end of the power cable;
a porcelain pipe in which the internal conductor is embedded;
a ground electrode embedded inside the insulator and formed to surround the internal conductor;
The inner peripheral surface of the insulator tube has an arrangement surface on which the stress cone attached to the power cable is arranged,
Further comprising a flange member having a mounting surface attached to the outside of the external equipment box and in contact with the insulator ,
When the side of the inner conductor to which the terminal of the power cable is connected is the base end side, and the side opposite to the base end side is the tip side,
The placement surface is arranged closer to the base end than the mounting surface,
The ground electrode is arranged closer to the distal end than the mounting surface,
insulator unit. An electric field shielding layer for shielding an electric field is formed on the outer peripheral surface of the porcelain insulator on the base end side of the ground electrode,
The porcelain pipe unit according to claim 1. When viewed from the radial direction, the ground electrode and the electric field shielding layer partially overlap each other.
The porcelain pipe unit according to claim 2. an embedded conductive member that is partially exposed and embedded in the porcelain pipe and electrically connected to the ground electrode;
further comprising a connection member electrically connected to the embedded conductive member and the flange member;
The flange member includes a flange mounting wall having the mounting surface, and a flange side wall formed on the base end side from the flange mounting wall and surrounding the insulator pipe,
The connection member is fixed to the inner peripheral side of the flange side wall,
The porcelain pipe unit according to any one of claims 1 to 3.

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